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Cohesin guides homology search during DNA repair using loops and sister chromatid linkages

Federico Teloni, Zsuzsanna Takács, Michael Mitter, Christoph C. H. Langer, Inès Prlesi, Thomas L. Steinacker, Vincent Reuter, Dmitry Evgenevich Mylarshchikov, Daniel W. Gerlich

2025Science12 citationsDOI

Abstract

Accurate repair of DNA double-strand breaks (DSBs) is essential for genome stability, and defective repair underlies diseases such as cancer. Homologous recombination uses an intact homologous sequence to faithfully restore damaged DNA, yet how broken DNA ends find homologous sites in a genome containing billions of bases remains unclear. Here, we introduce sister-pore-C, a high-resolution method to map intra- and intermolecular interactions in replicated chromosomes. We show how DSBs remodel chromosome architecture using two functionally distinct pools of cohesin. Loop-extruding cohesin accumulates across megabase-scale domains surrounding DSBs to control local homology sampling, whereas cohesive cohesin concentrates at break sites to tether DNA ends to the sister chromatid. This mechanism restricts the homology-sampling space, highlighting how chromosome conformation helps to preserve genomic integrity.

Topics & Concepts

CohesinHomologous recombinationHomologous chromosomeSister chromatidsBiologyEstablishment of sister chromatid cohesionChromosome segregationGeneticsDNADNA repairHomology directed repairHomology (biology)ChromatidGenomeCell biologyGenome instabilityChromosomeComputational biologyBase pairDNA sequencingCentromereRecombinationDNA Repair MechanismsAdvanced biosensing and bioanalysis techniquesGenomics and Chromatin Dynamics